Disruption and Compensation of Sulcation-based Covariance Networks in Neonatal Brain Growth After Perinatal Injury

Overview

Journal Cereb Cortex

Publisher Oxford University Press

Specialty Neurology

Date 2020 Jul 14

PMID 32656563

Citations 12

Authors

Sharon Y Kim

Mengting Liu

Seok-Jun Hong

Arthur W Toga

A James Barkovich

Duan Xu

Hosung Kim

Affiliations

Soon will be listed here.

Abstract

Perinatal brain injuries in preterm neonates are associated with alterations in structural neurodevelopment, leading to impaired cognition, motor coordination, and behavior. However, it remains unknown how such injuries affect postnatal cortical folding and structural covariance networks, which indicate functional parcellation and reciprocal brain connectivity. Studying 229 magnetic resonance scans from 158 preterm neonates (n = 158, mean age = 28.2), we found that severe injuries including intraventricular hemorrhage, periventricular leukomalacia, and ventriculomegaly lead to significantly reduced cortical folding and increased covariance (hyper-covariance) in only the early (<31 weeks) but not middle (31-35 weeks) or late stage (>35 weeks) of the third trimester. The aberrant hyper-covariance may drive acceleration of cortical folding as a compensatory mechanism to "catch-up" with normal development. By 40 weeks, preterm neonates with/without severe brain injuries exhibited no difference in cortical folding and covariance compared with healthy term neonates. However, graph theory-based analysis showed that even after recovery, severely injured brains exhibit a more segregated, less integrated, and overall inefficient network system with reduced integration strength in the dorsal attention, frontoparietal, limbic, and visual network systems. Ultimately, severe perinatal injuries cause network-level deviations that persist until the late stage of the third trimester and may contribute to neurofunctional impairment.

Citing Articles

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Structural covariance alterations reveal motor damage in periventricular leukomalacia.

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